U.S. patent application number 12/050658 was filed with the patent office on 2009-09-24 for eight speed planetary kinematic arrangement with two rotating clutches.
Invention is credited to Reid Alan Baldwin.
Application Number | 20090239699 12/050658 |
Document ID | / |
Family ID | 41089492 |
Filed Date | 2009-09-24 |
United States Patent
Application |
20090239699 |
Kind Code |
A1 |
Baldwin; Reid Alan |
September 24, 2009 |
Eight speed planetary kinematic arrangement with two rotating
clutches
Abstract
A multiple speed power transmission comprising: four epicyclic
gearing assemblies each having first, second, and third rotating
elements with specified interconnections, an input shaft connected
to one of the rotating elements, an output shaft, two rotating
clutches releasably connecting the input shaft to rotating
elements, and four brakes selectively holding rotating elements
against rotation. Clutches and brakes are applied in combinations
of two to produce eight forward ratios and one reverse ratio.
Inventors: |
Baldwin; Reid Alan; (Howell,
MI) |
Correspondence
Address: |
FORD GLOBAL TECHNOLOGIES, LLC
FAIRLANE PLAZA SOUTH, SUITE 800, 330 TOWN CENTER DRIVE
DEARBORN
MI
48126
US
|
Family ID: |
41089492 |
Appl. No.: |
12/050658 |
Filed: |
March 18, 2008 |
Current U.S.
Class: |
475/276 |
Current CPC
Class: |
F16H 2200/006 20130101;
F16H 2200/2046 20130101; F16H 3/66 20130101; F16H 3/666 20130101;
F16H 2200/2048 20130101; F16H 2200/2012 20130101 |
Class at
Publication: |
475/276 |
International
Class: |
F16H 3/62 20060101
F16H003/62 |
Claims
1. A multiple speed power transmission, comprising: first (20, 80,
or 90), second (30), third (40), and fourth (50) epicyclic gearing
assemblies each comprising first, second, and third rotating
elements, wherein: the second rotating element of the first
epicyclic gearing assembly (26, 84, or 94) is connected to the
first rotating element of the second epicyclic gearing assembly
(32); the second rotating element of the second epicyclic gearing
assembly (36) is connected to the third rotating element of the
third epicyclic gearing assembly (44); and the third rotating
element of the first epicyclic gearing assembly (24, 86, or 92),
the second rotating element of the third epicyclic gearing assembly
(46), and the third rotating element of the fourth epicyclic
gearing assembly (54) are mutually connected; a gearbox input shaft
(10) connected to the first rotating element of the third epicyclic
gearing assembly (42); and an output shaft (12) connected to the
third rotating element of the second epicyclic gearing assembly
(34) and the second rotating element of the fourth epicyclic
gearing assembly (56).
2. The multiple speed power transmission of claim 1, further
comprising: a first clutch (60) for releasably connecting gearbox
input shaft (10) to the first rotating element of the first
epicyclic gearing assembly (22, 82, or 96); a second clutch (62)
for releasably connecting gearbox input shaft (10) to the third
rotating element of the first epicyclic gearing assembly (24, 86,
or 92), the second rotating element of the third epicyclic gearing
assembly (46), and the third rotating element of the fourth
epicyclic gearing assembly (54); a first brake (64) for selectively
holding against rotation the first rotating element of the first
epicyclic gearing assembly (22, 82, or 96); a second brake (66) for
selectively holding against rotation the first rotating element of
the fourth epicyclic gearing assembly (52); and a third brake (70,
72) for selectively holding against rotation the second rotating
element of the second epicyclic gearing assembly (36) and the third
rotating element of the third epicyclic gearing assembly (44).
3. The multiple speed power transmission of claim 2, further
comprising: a fourth brake (68) for selectively holding against
rotation the second rotating element of the first epicyclic gearing
assembly (26, 84, or 94) and the first rotating element of the
second epicyclic gearing assembly (32).
4. The multiple speed power transmission of claim 2, wherein the
first epicyclic gearing assembly (20) is a simple planetary gear
set comprising: a sun gear (22) as the first rotating element; a
planet carrier (26) as the second rotating element; a ring gear
(24) as the third rotating element; and a set of planet gears (28)
supported for rotation on the planet carrier and in meshing
engagement with both the sun gear and the ring gear.
5. The multiple speed power transmission of claim 2, wherein the
second epicyclic gearing assembly (30) is a simple planetary gear
set comprising: a sun gear (32) as the first rotating element; a
planet carrier (36) as the second rotating element; a ring gear
(34) as the third rotating element; and a set of planet gears (38)
supported for rotation on the planet carrier and in meshing
engagement with both the sun gear and the ring gear.
6. The multiple speed power transmission of claim 2, wherein the
third epicyclic gearing assembly (40) is a simple planetary gear
set comprising: a sun gear (42) as the first rotating element; a
planet carrier (46) as the second rotating element; a ring gear
(44) as the third rotating element; and a set of planet gears (48)
supported for rotation on the planet carrier and in meshing
engagement with both the sun gear and the ring gear.
7. The multiple speed power transmission of claim 2, wherein the
fourth epicyclic gearing assembly (50) is a simple planetary gear
set comprising: a sun gear (52) as the first rotating element; a
planet carrier (56) as the second rotating element; a ring gear
(54) as the third rotating element; and a set of planet gears (58)
supported for rotation on the planet carrier and in meshing
engagement with both the sun gear and the ring gear.
8. The multiple speed power transmission of claim 2, wherein the
first epicyclic gearing assembly (80) is a compound planetary gear
set comprising: a sun gear (82) as the first rotating element; a
planet carrier (86) as the third rotating element; a ring gear (84)
as the second rotating element; a set of inner planet gears (88)
supported for rotation on the planet carrier and in meshing
engagement with the sun gear; and a set of outer planet gears (89)
supported for rotation on the planet carrier and in meshing
engagement with both the ring gear and the inner planet gears.
9. The multiple speed power transmission of claim 2, wherein the
first epicyclic gearing assembly (90) is a compound planetary gear
set comprising: a sun gear (92) as the third rotating element; a
planet carrier (96) as the first rotating element; a ring gear (94)
as the second rotating element; a set of inner planet gears (98)
supported for rotation on the planet carrier and in meshing
engagement with the sun gear; and a set of outer planet gears (99)
supported for rotation on the planet carrier and in meshing
engagement with both the ring gear and the inner planet gears.
10. The multiple speed power transmission of claim 2, wherein the
third brake comprises: a friction brake (70); and a one way clutch
(72).
11. The multiple speed power transmission of claim 2, further
comprising a fluid coupling or torque converter having: an impeller
(104) driven by an external power source; a turbine (106) driven
hydrodynamically by the impeller; a torsional isolator (114 or 116)
connecting the turbine to the gearbox input shaft (10) while
providing torsional compliance; and a third clutch for releasably
connecting the turbine to the impeller.
12. The multiple speed power transmission of claim 11, wherein: the
gearbox input shaft (10) is hollow; and the torsional isolator
(116) comprises a narrow shaft located inside the gearbox input
shaft.
13. The multiple speed power transmission of claim 2, further
comprising a fluid coupling or torque converter having: an impeller
(104) driven by an external power source; and a turbine (106)
driven hydrodynamically by the impeller and connected to the
gearbox input shaft (10).
14. The multiple speed power transmission of claim 13, further
comprising: a narrow shaft (116) located inside and connected to
the gearbox input shaft (10); and a third clutch (112) for
releasably connecting the external power source to the narrow
shaft.
15. The multiple speed power transmission of claim 13, further
comprising: a narrow shaft (116) located inside the gearbox input
shaft(10) and connected to the external power source; and a third
clutch (112) for releasably connecting the gearbox input shaft (10)
to the narrow shaft.
16. A multiple speed power transmission, comprising: first (20),
second (30), third (40), and fourth (50) planetary gear sets each
comprising a sun gear, a ring gear, a planet carrier, and a set of
pinion gears supported on the planet carrier and meshing with both
the sun gear and ring gear, wherein: the carrier of the first
planetary gear set (26) is connected to the sun gear of the second
planetary gear set (32); the planet carrier of the second planetary
gear set (36) is connected to the ring gear of the third planetary
gear set (44); and the ring gear of the first planetary gear set
(24), the planet carrier of the third planetary gear set (46), and
the ring gear of the fourth planetary gear set (54) are mutually
connected; a gearbox input shaft (10) connected to the sun gear of
the third planetary gear set (42); and an output shaft (12)
connected to the ring gear of the second planetary gear set (34)
and the planet carrier of the fourth planetary gear set (56).
17. The multiple speed power transmission of claim 16, further
comprising: a first clutch (60) for releasably connecting the
gearbox input shaft (10) to the sun gear of the first planetary
gear set (22); a second clutch (62) for releasably connecting the
gearbox input shaft (10) to the ring gear of the first planetary
gear set (24), the planet carrier of the third planetary gear set
(46), and the ring gear of the fourth planetary gear set (54); a
first brake (64) for selectively holding against rotation the sun
gear of the first planetary gear set (22); a second brake (66) for
selectively holding against rotation the sun gear of the fourth
planetary gear set (52); and a third brake (70, 72) for selectively
holding against rotation the planet carrier of the second planetary
gear set (36) and the ring gear of the third planetary gear set
(44); and a fourth brake (68) for selectively holding against
rotation the planet carrier of the first planetary gear set (26)
and the sun gear of the second planetary gear set (32).
18. A multiple speed power transmission, comprising: a first
planetary gear set (80 or 90) comprising a sun gear (82 or 92), a
ring gear (84 or 94), a planet carrier (86 or 96), an inner set of
planet gears (88 or 98) meshing with the sun gear, and an outer set
of pinion gears (89 or 99) meshing with both the inner planet gears
and ring gear; second (30), third (40), and fourth (50) planetary
gear sets each comprising a sun gear, a ring gear, a planet
carrier, and a set of pinion gears supported on the planet carrier
and meshing with both the sun gear and ring gear, wherein: the ring
gear of the first planetary gear set (84 or 94) is connected to the
sun gear of the second planetary gear set (32); the planet carrier
of the second planetary gear set (36) is connected to the ring gear
of the third planetary gear set (44); and the planet carrier of the
third planetary gear set (46), is connected to the ring gear of the
fourth planetary gear set (54); a gearbox input shaft (10)
connected to the sun gear of the third planetary gear set (42); an
output shaft (12) connected to the ring gear of the second
planetary gear set (34) and the planet carrier of the fourth
planetary gear set (56); a first brake (66) for selectively holding
against rotation the sun gear of the fourth planetary gear set
(52); a second brake (70, 72) for selectively holding against
rotation the planet carrier of the second planetary gear set (36)
and the ring gear of the third planetary gear set (44). a third
brake (68) for selectively holding against rotation the ring gear
of the first planetary gear set (84 or 94) and the sun gear of the
second planetary gear set (32).
19. The multiple speed power transmission of claim 18, wherein the
planet carrier of the planetary first gear set (86) is connected to
the planet carrier of the third planetary gear set (46) and the
ring gear of the fourth planetary gear set (54) and further
comprising: a first clutch (60) for releasably connecting the
gearbox input shaft (10) to the sun gear of the first planetary
gear set (82); a second clutch (62) for releasably connecting the
gearbox input shaft (10) to the planet carrier of the first
planetary gear set (86); and a fourth brake (64) for selectively
holding against rotation the sun gear of the first planetary gear
set (82);
20. The multiple speed power transmission of claim 18, wherein the
sun gear of the planetary first gear set (92) is connected to the
planet carrier of the third planetary gear set (46) and the ring
gear of the fourth planetary gear set (54) and further comprising:
a first clutch (60) for releasably connecting the gearbox input
shaft (10) to the planet carrier of the first planetary gear set
(96); a second clutch (62) for releasably connecting the gearbox
input shaft (10) to the sun gear of the first planetary gear set
(92); and a fourth brake (64) for selectively holding against
rotation the planet carrier of the first planetary gear set (96);
Description
BACKGROUND OF THE INVENTION
[0001] This invention relates to the field of automatic
transmissions for motor vehicles. More particularly, the invention
pertains to a kinematic arrangement of gearing, clutches, brakes,
and the interconnections among them in a power transmission.
BRIEF DESCRIPTION OF THE DRAWINGS
[0002] FIG. 1 is a schematic diagram of a transmission according to
a first embodiment of the present invention which produces eight
forward and one reverse speed ratios.
[0003] FIG. 2 is a table showing the proposed tooth numbers for the
gears of the transmission illustrated in FIG. 1.
[0004] FIG. 3 is a table indicating the states of the clutches and
resulting speed ratio of the transmission in FIG. 1 when the gears
have the number of teeth indicated in FIG. 2.
[0005] FIGS. 4-6 are schematic diagrams of alternative embodiments
which differ from the embodiment of FIG. 1 with respect to the
structure of the torque converter assembly.
[0006] FIGS. 7-8 are schematic diagrams of alternative embodiments
which differ from the embodiment of FIG. 1 with respect to the
structure of the first planetary gear set and its connections to
other components.
DETAILED DESCRIPTION OF THE INVENTION
[0007] A transmission according to a first embodiment of the
present invention is illustrated in FIG. 1. The transmission
contains four simple planetary gear set assemblies 20, 30, 40, and
50. Each simple planetary gear set assembly has a sun gear, a ring
gear with an internal mesh, a planet carrier, and a set of planet
gears supported for rotation on the carrier and meshing with both
the sun gear and ring gear. A recommended number of gear teeth for
each of these gears is shown in FIG. 2.
[0008] Gearbox input shaft 10 is driven by the vehicle's engine via
torque converter assembly 100. The third sun gear 42, is fixed to
gearbox input shaft 10. The first carrier 26 is connected to the
second sun gear 32. The second carrier 36 is connected to the third
ring gear 44. The first ring gear 24, third carrier 46, and fourth
ring gear 54 are mutually connected. A gearbox output shaft 12
drives the vehicle wheels, preferably via a driveshaft, a
differential assembly, and rear axle shafts. Gearbox output shaft
12 is fixed to the fourth carrier 56 and the second ring gear 34. A
transmission case 14 provides support for the gear sets, input
shaft, and output shaft.
[0009] Clutches 60 and 62 and brakes 64, 66, 68, and 70 are
preferably hydraulically actuated friction clutches which
releasably connect two elements when hydraulic pressure is applied
and disconnect those elements when the hydraulic pressure is
released. Clutch 60 releasably connects gearbox input shaft 10 to
the first sun gear 22. Clutch 62 releasably connects gearbox input
shaft 10 to the first ring gear 24, third carrier 46, and fourth
ring gear 54. Brake 64 releasably connects the first sun gear 22 to
the transmission case 14. Brake 66 releasably connects the fourth
sun gear 52 to the transmission case 14. Brake 68 releasably
connects the first carrier 26 and second sun gear 32 to the
transmission case 14. Brake 70 releasably connects the second
carrier 36 and the third ring gear 44 to the transmission case 14.
One way clutch 72 is a passive device which allows the second
carrier 36 and third ring gear 44 to rotate freely in a positive
direction but prevents rotation in the opposite direction.
[0010] Torque converter assembly 100 comprises an impeller 104 that
is driven by the transmission input shaft 102, stator 108, and
turbine 106. The stator 108 is connected to the transmission case
14 by a one way clutch 110. When the turbine is substantially
slower than the impeller, the one way clutch holds the stator
stationary and it provides a reaction torque to create torque
multiplication between the impeller and turbine. The one way clutch
overruns when the turbine speed is near or greater than the
impeller speed. Lock-up clutch 112 connects the turbine to the
impeller eliminating the hydrodynamic losses of the torque
converter. In FIG. 1, the turbine is connected to gearbox input
shaft 12 via a spring 114. This spring isolates the gearbox and
driveline from the torque pulses produced by the engine while
transmitting the average torque. A torque converter assembly with a
spring in this location is commonly called a turbine damper.
[0011] The transmission ratio is selected by applying hydraulic
pressure to two of the clutches and brakes as indicated in FIG.
3.
[0012] The transmission is prepared for forward motion in first
gear by applying brake 66. While the vehicle is at rest, turbine
106, gearbox input shaft 10, and all gear set components are
stationary. The engine drives impeller 104, which circulates fluid
toroidally among the impeller, stator, and turbine. This fluid flow
pattern produces a torque on the turbine shaft and gearbox input
shaft 10. One way clutch 72 provides a reaction at ring gear 44.
Clutch 66 provides another reaction at sun gear 52. Thus, a
multiple of the input torque is transferred to output shaft 12,
accelerating the vehicle.
[0013] In this condition, one way clutch 72 will overrun if an
attempt is made to transmit power in the opposite direction. If
engine braking behavior is desired, it is necessary to also apply
friction brake 70. Optionally, one way clutch 72 may be omitted and
friction brake 70 applied for both directions of power
transfer.
[0014] Lock-up clutch 112 may be applied any time the speed of
gearbox input shaft 10 is within the engine's operating range.
Preferably, it is applied as soon as possible and remains engaged
as long as possible in order to minimize transmission parasitic
losses.
[0015] To shift to second gear, brake 68 is progressively engaged,
maintaining brake 66 fully applied. As the torque capacity of brake
68 increases, one way clutch 72 will overrun. If one way clutch 72
is omitted, brake 70 must be progressively released as brake 68 is
engaged.
[0016] To shift from second to third gear, brake 64 is
progressively engaged while brake 68 is progressively released. To
shift from third to fourth gear, clutch 60 is progressively engaged
while brake 64 is progressively released. To shift from fourth to
fifth gear, clutch 62 is progressively engaged while clutch 60 is
progressively released. Brake 66 is maintained in the fully applied
state through all of these transitions.
[0017] To shift from fifth to sixth gear, clutch 60 is
progressively engaged while brake 66 is progressively released.
Sixth gear is a direct drive gear. To shift from sixth to seventh
gear, brake 64 is progressively engaged while clutch 60 is
progressively released. To shift from seventh to eighth gear, brake
68 is progressively engaged while brake 64 is progressively
released. Clutch 62 is maintained in the fully applied state
through all of these transitions.
[0018] Downshifting to a lower gear is accomplished by reversing
the steps described above for the corresponding upshift.
[0019] The transmission is operated in reverse by applying clutch
60 and brake 70.
[0020] FIGS. 4, 5, and 6 illustrate alternate embodiments that
differ from the above embodiment with respect to the construction
and function of torque converter assembly 100. These embodiments
are operated in the same fashion as the previous embodiment.
[0021] In the embodiment of FIG. 4, a relatively narrow shaft 116
runs through the center of the gearbox inside gearbox input shaft
10, which is hollow. Shafts 116 and 10 are connected to each other
as far from the input end of the transmission as feasible. The
diameter of shaft 116 is selected just large enough to withstand
the maximum anticipated turbine torque (with an appropriate safety
factor). As a result of its small diameter and relatively long
length, shaft 116 has considerable torsional compliance and
provides isolation from engine pulses (which was accomplished by
spring 114 in the embodiment of FIG. 1). In this embodiment,
turbine 106 is connected to shaft 116 as opposed to shaft 10. The
remaining components and their interconnections are identical to
the embodiment of FIG. 1.
[0022] The embodiment of FIG. 5 also uses a narrow shaft 116 to
provide isolation from engine pulses. In this embodiment, however,
the turbine is connected to gearbox input shaft 10 and lock-up
clutch 112 releasably connects transmission input shaft 102 to
shaft 116. Shaft 116 may be designed to withstand engine torque as
opposed to turbine torque which is typically much higher. As a
result, it has more compliance and provides better isolation.
[0023] In the embodiment of FIG. 6, lock-up clutch 112 is located
within the gearbox portion and releasably connects the narrow shaft
116 to gearbox input shaft 10. Turbine 106 is connected to gearbox
input shaft 10. Shaft 116 is connected to transmission input shaft
102. The fluid that actuates clutch 112 may be fed through output
shaft 12.
[0024] FIGS. 7 and 8 illustrate alternate embodiments which differ
with respect to the previous embodiments with respect to the
construction of the first gear set and its connections. Torque
converter assembly 100 is not shown in these Figures. Any of the
variations of torque converter illustrated in FIGS. 1, 4, 5, and 6
and described above could be utilized with the gearbox structures
illustrated in FIGS. 7 and 8. The embodiments illustrated in FIGS.
7 and 8 are operated in the same fashion as the embodiment
illustrated in FIG. 1 which is described above.
[0025] A transmission according to another embodiment of the
present invention is illustrated in FIG. 7. The transmission
contains one compound planetary gear set assembly 80 and three
simple planetary gear set assemblies 30, 40, and 50. The compound
planetary gear set assembly has a sun gear, a ring gear with an
internal mesh, a planet carrier, an inner set of planet gears
supported for rotation on the carrier and meshing with the sun
gear, and an outer set of planet gears supported for rotation on
the carrier and meshing with both one of the inner planet gears and
the ring gear.
[0026] The third sun gear 42, is fixed to gearbox input shaft 10.
The first ring gear 84 is connected to the second sun gear 32. The
second carrier 36 is connected to the third ring gear 44. The first
carrier 86, third carrier 46, and fourth ring gear 54 are mutually
connected. Output shaft 12 is fixed to the fourth carrier 56 and
the second ring gear 34. A transmission case 14 provides support
for the gear sets, input shaft, and output shaft.
[0027] Clutch 60 releasably connects gearbox input shaft 10 to the
first sun gear 82. Clutch 62 releasably connects gearbox input
shaft 10 to the first carrier 86, third carrier 46, and fourth ring
gear 54. Brake 64 releasably connects the first sun gear 82 to the
transmission case 14. Brake 66 releasably connects the fourth sun
gear 52 to the transmission case 14. Brake 68 releasably connects
the first ring gear 84 and second sun gear 32 to the transmission
case 14. Brake 70 releasably connects the second carrier 38 and the
third ring gear 44 to the transmission case 14. One way clutch 72
allows the second carrier 36 and third ring gear 44 to rotate
freely in a positive direction but prevents rotation in the
opposite direction.
[0028] A transmission according to another embodiment of the
present invention is illustrated in FIG. 8. The transmission
contains one compound planetary gear set assembly 90 and three
simple planetary gear set assemblies 30, 40, and 50. The third sun
gear 42, is fixed to gearbox input shaft 10. The first ring gear 94
is connected to the second sun gear 32. The second carrier 36 is
connected to the third ring gear 44. The first sun gear 92, third
carrier 46, and fourth ring gear 54 are mutually connected. Output
shaft 12 is fixed to the fourth carrier 56 and the second ring gear
34. A transmission case 14 provides support for the gear sets,
input shaft, and output shaft.
[0029] Clutch 60 releasably connects gearbox input shaft 10 to the
first carrier 96. Clutch 62 releasably connects gearbox input shaft
10 to the first sun gear 92, third carrier 46, and fourth ring gear
54. Brake 64 releasably connects the first carrier 96 to the
transmission case 14. Brake 66 releasably connects the fourth sun
gear 52 to the transmission case 14. Brake 68 releasably connects
the first ring gear 94 and second sun gear 32 to the transmission
case 14. Brake 70 releasably connects the second carrier 38 and the
third ring gear 44 to the transmission case 14. One way clutch 72
allows the second carrier 36 and third ring gear 44 to rotate
freely in a positive direction but prevents rotation in the
opposite direction.
[0030] A transmission embodiment according to this invention
contain four epicyclic gearing assemblies, each with three members
that rotate around a common axis. In each epicyclic gearing
assembly, the speeds of the three elements are linearly related.
The second rotating elements is constrained to rotate at a speed
which is a weighted average of the speeds of the first and third
elements. The weighting factors are determined by the configuration
of the epicyclic gearing assembly and the ratios of the numbers of
gear teeth. In FIG. 1, all four epicyclic gearing assemblies are
simple planetary gearsets. In FIGS. 7 and 8, one of the epicyclic
gearing assemblies is a compound planetary gearset. Other types of
epicyclic gearing assemblies, such as coplanar gear loops as
described in U.S. Pat. Nos. 5,030,184 and 6,126,566, are known and
may be substituted without departing from the present
invention.
[0031] In accordance with the provisions of the patent statutes,
the preferred embodiment has been described. However, it should be
noted that alternate embodiments can be practiced otherwise than as
specifically illustrated and described.
* * * * *